References
[1]. Buffolo, M. et al. (2024). Review and Outlook on GaN and SiC Power Devices: Industrial State-of-the-Art, Applications, and Perspectives. IEEE transactions on electron devices 71 (3): 1344–1355.
[2]. Sokolovskij, R. et al. (2019). Recessed Gate Pt-AlGaN/GaN HEMT H2 Sensor. 2019 IEEE SENSORS: 1–4.
[3]. Zhang, Nan, Qijie Xie, and Siqi Jia. (2022). Development of Solution-Processed Perovskite Semiconductors Lasers. Crystals (Basel) 12 (9): 1274.
[4]. Stoumpos, Constantinos C, and Mercouri G Kanatzidis. (2015). The Renaissance of Halide Perovskites and Their Evolution as Emerging Semiconductors. Accounts of chemical research 48(10): 2791–2802.
[5]. Hossain, M. Khalid et al. (2023). Numerical Analysis in DFT and SCAPS-1D on the Influence of Different Charge Transport Layers of CsPbBr3 Perovskite Solar Cells. Energy & fuels 37 (8): 6078–6098.
[6]. Eperon, Giles E et al. (2014). Formamidinium Lead Trihalide: A Broadly Tunable Perovskite for Efficient Planar Heterojunction Solar Cells. Energy & environmental science 7 (3): 982–988.
[7]. Zhang, Weina et al. (2025). FAPbI3-Nanoparticles with Ligands Act Synergistically in Absorbent Layers for High-Performance and Stable FAPbI3 Based Perovskite Solar Cells.” Nano energy 133: 110476.
[8]. Prasanna, Rohit et al. (2017). Band Gap Tuning via Lattice Contraction and Octahedral Tilting in Perovskite Materials for Photovoltaics. Journal of the American Chemical Society 139 (32): 11117–11124.
[9]. Aranda, Clara A. et al. (2024). Overcoming Ionic Migration in Perovskite Solar Cells through Alkali Metals. Joule 8 (1): 241–254.
[10]. Kumar, Mulmudi Hemant et al. (2014). Lead-Free Halide Perovskite Solar Cells with High Photocurrents Realized Through Vacancy Modulation. Advanced materials (Weinheim) 26 (41): 7122–7127.
[11]. Wang, Wei et al. (2024). Bio-Inspired Engineering of Anti-Aging Natural Cyanidin toward Air-Stable Tin-Based Perovskite Solar Cells. ACS sustainable chemistry & engineering 12(2): 1019–1028.
[12]. Chabri, I. et al. (2023). Enhance Stability of γ-CsSnI3-Based PSCs by (γ-CsSnI3-Cs2SnI6) Heterojunction. Solar energy materials and solar cells 259: 112426.
[13]. Monteiro, D.A., M.M. Costa, and R.R.F. Bento. (2021). Structural Refinement, Morphological and Electrical Properties of BaZrO3:Bi(Zn1/2Ti1/2)O3 Lead-Free Ceramics. Journal of alloys and compounds 868: 159221.
[14]. Wang, Rui et al. (2021). Prospects for Metal Halide Perovskite-Based Tandem Solar Cells. Nature photonics 15(6): 411–425.
[15]. Jošt, Marko et al. (2020). Monolithic Perovskite Tandem Solar Cells: A Review of the Present Status and Advanced Characterization Methods Toward 30% Efficiency. Advanced energy materials 10 (26): n/a.
[16]. Ke, Lili et al. (2021). Factors Influencing the Nucleation and Crystal Growth of Solution-Processed Organic Lead Halide Perovskites: A Review. Journal of physics. D, Applied physics 54 (16): 163001.
[17]. XIAO, Zichen et al. (2024). Nanofiber-Modified Electron Transport Layer for Perovskite Solar Cells. Wu ji cai liao xue bao 39 (7): 828.
[18]. Xi, Jiahao et al. (2022). Efficient Perovskite Solar Cells Based on Tin Oxide Nanocrystals with Difunctional Modification. Small (Weinheim an der Bergstrasse, Germany) 18 (33): e2203519-n/a.
[19]. Ma, Chunqing et al. (2021). Dynamic Halide Perovskite Heterojunction Generates Direct Current. Energy & environmental science 14(1): 374–381.
[20]. Zhuo, Xiao et al. (2024). Ultrafast Dynamics of Photoexcited Carriers in Tellurium in the Vicinity of Weyl Nodes. Physical review. B 110(1): 014311.
[21]. Liu, Ye et al. (2021). Ligand Assisted Growth of Perovskite Single Crystals with Low Defect Density. Nature communications 12 (1): 1686.
[22]. Maiti, Abhishek et al. (2020). Defects and Their Passivation in Hybrid Halide Perovskites toward Solar Cell Applications. Solar RRL 4 (12): n/a.
[23]. Wehrenfennig, Christian et al. (2014). High Charge Carrier Mobilities and Lifetimes in Organolead Trihalide Perovskites. Advanced materials (Weinheim) 26(10): 1584–1589.
[24]. Han, G. S. et al. (2019). Spin-coating process for 10 cm × 10 cm perovskite solar modules enabled by self-assembly of SnO2 nanocolloids. ACS Energy Lett. 4(8):1845–1851.
[25]. Li, Jing et al. (2024). Ultralong Compositional Gradient Perovskite Nanowires Fabricated by Source-Limiting Anion Exchange. ACS nano 18 (45): 30978–30986.
[26]. Bandara, R. M. I et al. (2019). Tin() Dopant Removal through Anti-Solvent Engineering Enabling Tin Based Perovskite Solar Cells with High Charge Carrier Mobilities. Journal of materials chemistry. C, Materials for optical and electronic devices 7(27): 8389–8397.
[27]. Rahman, Mohammad Wahidur et al. (2021). Hybrid BaTiO3/SiNx/AlGaN/GaN Lateral Schottky Barrier Diodes with Low Turn-on and High Breakdown Performance. Applied physics letters 119 (1).
[28]. Zhang, Chi et al. (2022). Long-Range Transport and Ultrafast Interfacial Charge Transfer in Perovskite/Monolayer Semiconductor Heterostructure for Enhanced Light Absorption and Photocarrier Lifetime. The Journal of chemical physics 156(24): 244701.
[29]. Chen, Bingbing et al. (2022). A Two-Step Solution-Processed Wide-Bandgap Perovskite for Monolithic Silicon-Based Tandem Solar Cells with >27% Efficiency. ACS energy letters 7 (8): 2771–2780.
[30]. Peng, Wei et al. (2023). Reducing Nonradiative Recombination in Perovskite Solar Cells with a Porous Insulator Contact. Science (American Association for the Advancement of Science) 379(6633): 683–690.
[31]. Paulus, F.; Tyznik, C.; Jurchescu, O.D.; Vaynzof, Y. (2021). Switched-On: Progress, Challenges, and Opportunities in Metal Halide Perovskite Transistors. Adv. Funct. Mater. 31(29).
[32]. Mei, Y. et al. (2015). Electrostatic Gating of Hybrid Halide Perovskite Field-Effect Transistors: Balanced Ambipolar Transport at Room-Temperature. MRS communications 5 (2): 297–301.
[33]. Kim, Hyeong Pil et al. (2020). A Hysteresis-Free Perovskite Transistor with Exceptional Stability through Molecular Cross-Linking and Amine-Based Surface Passivation. Nanoscale 12(14): 7641–765.
[34]. Gedda, Murali et al. (2021). Ruddlesden–Popper‐Phase Hybrid Halide Perovskite/Small‐Molecule Organic Blend Memory Transistors. Advanced materials (Weinheim) 33(7).
[35]. Liang, Yuhang, Feng Li, and Rongkun Zheng. (2020). Low‐Dimensional Hybrid Perovskites for Field‐Effect Transistors with Improved Stability: Progress and Challenges. Advanced electronic materials 6 (9): n/a.
[36]. Haziq, Muhaimin et al. (2022). Challenges and Opportunities for High-Power and High-Frequency AlGaN/GaN High-Electron-Mobility Transistor (HEMT) Applications: A Review. Micromachines (Basel) 13 (12): 2133.
[37]. Hong, Xitong et al. (2022). Two‐Dimensional Perovskite‐Gated AlGaN/GaN High‐Electron‐Mobility‐Transistor for Neuromorphic Vision Sensor. Advanced science 9(27): e2202019-n/a.
[38]. Li G J. (2020). Study on heterogeneous epitaxy integration of functional oxide thin films and enhanced HEMT devices [D]. Shanghai Institute of Silicate, University of Chinese Academy of Sciences,
[39]. Upadhyaya, Aditi et al. (2019). Analysis of Perovskite Based Schottky Photodiode. AIP conference proceedings 2100(1)
[40]. Nayak, Monisha et al. (2022). Schottky Analysis of Formamidinium Lead Halide Perovskite Nanocrystals Devices with Enhanced Stability. Applied nanoscience 12(9): 2671–2681.
[41]. Akinbami, O et al. (2021). The Effect of Temperature and Time on the Properties of 2D Cs2ZnBr4 Perovskite Nanocrystals and Their Application in a Schottky Barrier Device. Journal of materials chemistry. C, Materials for optical and electronic devices 9(18): 6022–6033.
[42]. Li, Yujiao et al. (2021). Heterostructural Perovskite Solar Cell Constructed with Li-Doped p-MAPbI3/n-TiO2 PN Junction. Solar energy 226: 446–454.
[43]. Schramm, Tim et al. (2024). Electrical Doping of Metal Halide Perovskites by Co‐Evaporation and Application in PN Junctions. Advanced materials (Weinheim) 36(29): e2314289-n/a.
Cite this article
Zhang,J. (2025). Research on the Application of Novel Perovskite Materials in Wide-Bandgap Power Electronic Devices. Applied and Computational Engineering,162,122-129.
Data availability
The datasets used and/or analyzed during the current study will be available from the authors upon reasonable request.
Disclaimer/Publisher's Note
The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of EWA Publishing and/or the editor(s). EWA Publishing and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.
About volume
Volume title: Proceedings of CONF-FMCE 2025 Symposium: Semantic Communication for Media Compression and Transmission
© 2024 by the author(s). Licensee EWA Publishing, Oxford, UK. This article is an open access article distributed under the terms and
conditions of the Creative Commons Attribution (CC BY) license. Authors who
publish this series agree to the following terms:
1. Authors retain copyright and grant the series right of first publication with the work simultaneously licensed under a Creative Commons
Attribution License that allows others to share the work with an acknowledgment of the work's authorship and initial publication in this
series.
2. Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the series's published
version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgment of its initial
publication in this series.
3. Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and
during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work (See
Open access policy for details).
References
[1]. Buffolo, M. et al. (2024). Review and Outlook on GaN and SiC Power Devices: Industrial State-of-the-Art, Applications, and Perspectives. IEEE transactions on electron devices 71 (3): 1344–1355.
[2]. Sokolovskij, R. et al. (2019). Recessed Gate Pt-AlGaN/GaN HEMT H2 Sensor. 2019 IEEE SENSORS: 1–4.
[3]. Zhang, Nan, Qijie Xie, and Siqi Jia. (2022). Development of Solution-Processed Perovskite Semiconductors Lasers. Crystals (Basel) 12 (9): 1274.
[4]. Stoumpos, Constantinos C, and Mercouri G Kanatzidis. (2015). The Renaissance of Halide Perovskites and Their Evolution as Emerging Semiconductors. Accounts of chemical research 48(10): 2791–2802.
[5]. Hossain, M. Khalid et al. (2023). Numerical Analysis in DFT and SCAPS-1D on the Influence of Different Charge Transport Layers of CsPbBr3 Perovskite Solar Cells. Energy & fuels 37 (8): 6078–6098.
[6]. Eperon, Giles E et al. (2014). Formamidinium Lead Trihalide: A Broadly Tunable Perovskite for Efficient Planar Heterojunction Solar Cells. Energy & environmental science 7 (3): 982–988.
[7]. Zhang, Weina et al. (2025). FAPbI3-Nanoparticles with Ligands Act Synergistically in Absorbent Layers for High-Performance and Stable FAPbI3 Based Perovskite Solar Cells.” Nano energy 133: 110476.
[8]. Prasanna, Rohit et al. (2017). Band Gap Tuning via Lattice Contraction and Octahedral Tilting in Perovskite Materials for Photovoltaics. Journal of the American Chemical Society 139 (32): 11117–11124.
[9]. Aranda, Clara A. et al. (2024). Overcoming Ionic Migration in Perovskite Solar Cells through Alkali Metals. Joule 8 (1): 241–254.
[10]. Kumar, Mulmudi Hemant et al. (2014). Lead-Free Halide Perovskite Solar Cells with High Photocurrents Realized Through Vacancy Modulation. Advanced materials (Weinheim) 26 (41): 7122–7127.
[11]. Wang, Wei et al. (2024). Bio-Inspired Engineering of Anti-Aging Natural Cyanidin toward Air-Stable Tin-Based Perovskite Solar Cells. ACS sustainable chemistry & engineering 12(2): 1019–1028.
[12]. Chabri, I. et al. (2023). Enhance Stability of γ-CsSnI3-Based PSCs by (γ-CsSnI3-Cs2SnI6) Heterojunction. Solar energy materials and solar cells 259: 112426.
[13]. Monteiro, D.A., M.M. Costa, and R.R.F. Bento. (2021). Structural Refinement, Morphological and Electrical Properties of BaZrO3:Bi(Zn1/2Ti1/2)O3 Lead-Free Ceramics. Journal of alloys and compounds 868: 159221.
[14]. Wang, Rui et al. (2021). Prospects for Metal Halide Perovskite-Based Tandem Solar Cells. Nature photonics 15(6): 411–425.
[15]. Jošt, Marko et al. (2020). Monolithic Perovskite Tandem Solar Cells: A Review of the Present Status and Advanced Characterization Methods Toward 30% Efficiency. Advanced energy materials 10 (26): n/a.
[16]. Ke, Lili et al. (2021). Factors Influencing the Nucleation and Crystal Growth of Solution-Processed Organic Lead Halide Perovskites: A Review. Journal of physics. D, Applied physics 54 (16): 163001.
[17]. XIAO, Zichen et al. (2024). Nanofiber-Modified Electron Transport Layer for Perovskite Solar Cells. Wu ji cai liao xue bao 39 (7): 828.
[18]. Xi, Jiahao et al. (2022). Efficient Perovskite Solar Cells Based on Tin Oxide Nanocrystals with Difunctional Modification. Small (Weinheim an der Bergstrasse, Germany) 18 (33): e2203519-n/a.
[19]. Ma, Chunqing et al. (2021). Dynamic Halide Perovskite Heterojunction Generates Direct Current. Energy & environmental science 14(1): 374–381.
[20]. Zhuo, Xiao et al. (2024). Ultrafast Dynamics of Photoexcited Carriers in Tellurium in the Vicinity of Weyl Nodes. Physical review. B 110(1): 014311.
[21]. Liu, Ye et al. (2021). Ligand Assisted Growth of Perovskite Single Crystals with Low Defect Density. Nature communications 12 (1): 1686.
[22]. Maiti, Abhishek et al. (2020). Defects and Their Passivation in Hybrid Halide Perovskites toward Solar Cell Applications. Solar RRL 4 (12): n/a.
[23]. Wehrenfennig, Christian et al. (2014). High Charge Carrier Mobilities and Lifetimes in Organolead Trihalide Perovskites. Advanced materials (Weinheim) 26(10): 1584–1589.
[24]. Han, G. S. et al. (2019). Spin-coating process for 10 cm × 10 cm perovskite solar modules enabled by self-assembly of SnO2 nanocolloids. ACS Energy Lett. 4(8):1845–1851.
[25]. Li, Jing et al. (2024). Ultralong Compositional Gradient Perovskite Nanowires Fabricated by Source-Limiting Anion Exchange. ACS nano 18 (45): 30978–30986.
[26]. Bandara, R. M. I et al. (2019). Tin() Dopant Removal through Anti-Solvent Engineering Enabling Tin Based Perovskite Solar Cells with High Charge Carrier Mobilities. Journal of materials chemistry. C, Materials for optical and electronic devices 7(27): 8389–8397.
[27]. Rahman, Mohammad Wahidur et al. (2021). Hybrid BaTiO3/SiNx/AlGaN/GaN Lateral Schottky Barrier Diodes with Low Turn-on and High Breakdown Performance. Applied physics letters 119 (1).
[28]. Zhang, Chi et al. (2022). Long-Range Transport and Ultrafast Interfacial Charge Transfer in Perovskite/Monolayer Semiconductor Heterostructure for Enhanced Light Absorption and Photocarrier Lifetime. The Journal of chemical physics 156(24): 244701.
[29]. Chen, Bingbing et al. (2022). A Two-Step Solution-Processed Wide-Bandgap Perovskite for Monolithic Silicon-Based Tandem Solar Cells with >27% Efficiency. ACS energy letters 7 (8): 2771–2780.
[30]. Peng, Wei et al. (2023). Reducing Nonradiative Recombination in Perovskite Solar Cells with a Porous Insulator Contact. Science (American Association for the Advancement of Science) 379(6633): 683–690.
[31]. Paulus, F.; Tyznik, C.; Jurchescu, O.D.; Vaynzof, Y. (2021). Switched-On: Progress, Challenges, and Opportunities in Metal Halide Perovskite Transistors. Adv. Funct. Mater. 31(29).
[32]. Mei, Y. et al. (2015). Electrostatic Gating of Hybrid Halide Perovskite Field-Effect Transistors: Balanced Ambipolar Transport at Room-Temperature. MRS communications 5 (2): 297–301.
[33]. Kim, Hyeong Pil et al. (2020). A Hysteresis-Free Perovskite Transistor with Exceptional Stability through Molecular Cross-Linking and Amine-Based Surface Passivation. Nanoscale 12(14): 7641–765.
[34]. Gedda, Murali et al. (2021). Ruddlesden–Popper‐Phase Hybrid Halide Perovskite/Small‐Molecule Organic Blend Memory Transistors. Advanced materials (Weinheim) 33(7).
[35]. Liang, Yuhang, Feng Li, and Rongkun Zheng. (2020). Low‐Dimensional Hybrid Perovskites for Field‐Effect Transistors with Improved Stability: Progress and Challenges. Advanced electronic materials 6 (9): n/a.
[36]. Haziq, Muhaimin et al. (2022). Challenges and Opportunities for High-Power and High-Frequency AlGaN/GaN High-Electron-Mobility Transistor (HEMT) Applications: A Review. Micromachines (Basel) 13 (12): 2133.
[37]. Hong, Xitong et al. (2022). Two‐Dimensional Perovskite‐Gated AlGaN/GaN High‐Electron‐Mobility‐Transistor for Neuromorphic Vision Sensor. Advanced science 9(27): e2202019-n/a.
[38]. Li G J. (2020). Study on heterogeneous epitaxy integration of functional oxide thin films and enhanced HEMT devices [D]. Shanghai Institute of Silicate, University of Chinese Academy of Sciences,
[39]. Upadhyaya, Aditi et al. (2019). Analysis of Perovskite Based Schottky Photodiode. AIP conference proceedings 2100(1)
[40]. Nayak, Monisha et al. (2022). Schottky Analysis of Formamidinium Lead Halide Perovskite Nanocrystals Devices with Enhanced Stability. Applied nanoscience 12(9): 2671–2681.
[41]. Akinbami, O et al. (2021). The Effect of Temperature and Time on the Properties of 2D Cs2ZnBr4 Perovskite Nanocrystals and Their Application in a Schottky Barrier Device. Journal of materials chemistry. C, Materials for optical and electronic devices 9(18): 6022–6033.
[42]. Li, Yujiao et al. (2021). Heterostructural Perovskite Solar Cell Constructed with Li-Doped p-MAPbI3/n-TiO2 PN Junction. Solar energy 226: 446–454.
[43]. Schramm, Tim et al. (2024). Electrical Doping of Metal Halide Perovskites by Co‐Evaporation and Application in PN Junctions. Advanced materials (Weinheim) 36(29): e2314289-n/a.